Lesson 1

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Transcript Lesson 1 

5-1
5-1 Variation
Variation Functions
Functions
Warm Up
Lesson Presentation
Lesson Quiz
HoltMcDougal
Algebra 2Algebra 2
Holt
Variation Functions
5-1
Warm Up
Solve each equation.
2.4 = 2
10.8
x
9
2. 1.6x = 1.8(24.8) 27.9
Determine whether each data set could
represent a linear function.
1.
3.
x
y
2
12
4
6
4.
x
y
–2 –1
–6 –2
Holt McDougal Algebra 2
6
4
8
3
no
0
2
1
6
yes
5-1
Variation Functions
Objective
Solve problems involving direct,
inverse, joint, and combined variation.
Holt McDougal Algebra 2
5-1
Variation Functions
Vocabulary
direct variation
constant of variation
joint variation
inverse variation
combined variation
Holt McDougal Algebra 2
5-1
Variation Functions
In Chapter 2, you studied many types of linear
functions. One special type of linear function is
called direct variation. A direct variation is a
relationship between two variables x and y that can
be written in the form y = kx, where k ≠ 0. In this
relationship, k is the constant of variation. For
the equation y = kx, y varies directly as x.
Holt McDougal Algebra 2
5-1
Variation Functions
A direct variation equation is a linear equation in
the form y = mx + b, where b = 0 and the
constant of variation k is the slope. Because b = 0,
the graph of a direct variation always passes
through the origin.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 1: Writing and Graphing Direct Variation
Given: y varies directly as x, and y = 27 when
x = 6. Write and graph the direct variation
function.
y = kx
y varies directly as x.
27 = k(6)
Substitute 27 for y and 6 for x.
k = 4.5
Solve for the constant of variation k.
y = 4.5x
Write the variation function by using
the value of k.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 1 Continued
Graph the direct
variation function.
The y-intercept is 0,
and the slope is 4.5.
Check Substitute the
original values of x and
y into the equation.
y = 4.5x
27
4.5(6)
27
27 
Holt McDougal Algebra 2
5-1
Variation Functions
Helpful Hint
If k is positive in a direct variation, the
value of y increases as the value of x
increases.
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 1
Given: y varies directly as x, and y = 6.5 when
x = 13. Write and graph the direct variation
function.
y = kx
6.5 = k(13)
y varies directly as x.
Substitute 6.5 for y and 13 for x.
k = 0.5
Solve for the constant of variation k.
y = 0.5x
Write the variation function by using
the value of k.
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 1 Continued
Graph the direct
variation function.
The y-intercept is 0,
and the slope is 0.5.
Check Substitute the
original values of x and
y into the equation.
y = 0.5x
6.5
0.5(13)
6.5
6.5 
Holt McDougal Algebra 2
5-1
Variation Functions
When you want to find specific values in a direct
variation problem, you can solve for k and then use
substitution or you can use the proportion derived
below.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 2: Solving Direct Variation Problems
The cost of an item in euros e varies
directly as the cost of the item in dollars d,
and e = 3.85 euros when d = $5.00. Find d
when e = 10.00 euros.
Method 1 Find k.
e = kd
3.85 = k(5.00)
0.77 = k
Substitute.
Solve for k.
Write the variation function.
Use 0.77 for k.
e = 0.77d
Substitute 10.00 for e.
10.00 = 0.77d
12.99 ≈ d
Holt McDougal Algebra 2
Solve for d.
5-1
Variation Functions
Example 2 Continued
Method 2 Use a proportion.
e1
e2
=
d1
d2
3.85
10.00
=
5.00
d
Substitute.
3.85d = 50.00
Find the cross products.
12.99 ≈ d
Solve for d.
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 2
The perimeter P of a regular dodecagon varies
directly as the side length s, and P = 18 in.
when s = 1.5 in. Find s when P = 75 in.
Method 1 Find k.
P = ks
Substitute.
18 = k(1.5)
Solve for k.
12 = k
Write the variation function.
Use 12 for k.
P = 12s
75 = 12s
6.25 ≈ s
Holt McDougal Algebra 2
Substitute 75 for P.
Solve for s.
5-1
Variation Functions
Check It Out! Example 2 Continued
Method 2 Use a proportion.
P1
P2
=
s1
s2
18
75
=
1.5
s
Substitute.
18s = 112.5
Find the cross products.
6.25 = s
Solve for s.
Holt McDougal Algebra 2
5-1
Variation Functions
A joint variation is a relationship among
three variables that can be written in the
form y = kxz, where k is the constant of
variation. For the equation y = kxz, y varies
jointly as x and z.
Reading Math
The phrases “y varies directly as x” and “y is
directly proportional to x” have the same
meaning.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 3: Solving Joint Variation Problems
The volume V of a cone varies jointly as the
area of the base B and the height h, and
V = 12 ft3 when B = 9 ft3 and h = 4 ft. Find B
when V = 24 ft3 and h = 9 ft.
Step 1 Find k.
V = kBh
12 = k(9)(4) Substitute.
1 =k
Solve for k.
3
Step 2 Use the variation
function.
1
1 for k.
V = Bh
Use
3
3
1
24 = B(9) Substitute.
3
8 = B
The base is 8 ft2.
Holt McDougal Algebra 2
Solve for B.
5-1
Variation Functions
Check It Out! Example 3
The lateral surface area L of a cone varies
jointly as the area of the base radius r and the
slant height l, and L = 63 m2 when r = 3.5 m
and l = 18 m. Find r to the nearest tenth when
L = 8 m2 and l = 5 m.
Step 1 Find k.
L = krl
Step 2 Use the variation
function.
63 = k(3.5)(18) Substitute.
=k
Holt McDougal Algebra 2
Solve for k.
L = rl
Use  for k.
8 = r(5)
Substitute.
1.6 = r
Solve for r.
5-1
Variation Functions
A third type of variation
describes a situation in
which one quantity increases
and the other decreases. For
example, the table shows
that the time needed to
drive 600 miles decreases
as speed increases.
This type of variation is an inverse variation. An
inverse variation is a relationship between two
variables x and y that can be written in the form
y = k , where k ≠ 0. For the equation y = k ,
x
x
y varies inversely as x.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 4: Writing and Graphing Inverse Variation
Given: y varies inversely as x, and y = 4
when x = 5. Write and graph the inverse
variation function.
y= k
x
4= k
5
k = 20
y = 20
x
Holt McDougal Algebra 2
y varies inversely as x.
Substitute 4 for y and
5 for x.
Solve for k.
Write the variation
formula.
Variation Functions
5-1
Example 4 Continued
To graph, make a table of values for both positive
and negative values of x. Plot the points, and
connect them with two smooth curves. Because
division by 0 is undefined, the function is
undefined when x = 0.
x
–2
–4
–6
–8
y
–10
–5
– 10
3
– 25
Holt McDougal Algebra 2
x
2
4
6
8
y
10
5
10
3
5
2
5-1
Variation Functions
Check It Out! Example 4
Given: y varies inversely as x, and y = 4
when x = 10. Write and graph the inverse
variation function.
y= k
x
4= k
10
k = 40
y = 40
x
Holt McDougal Algebra 2
y varies inversely as x.
Substitute 4 for y and
10 for x.
Solve for k.
Write the variation
formula.
5-1
Variation Functions
Check It Out! Example 4 Continued
To graph, make a table of values for both positive and
negative values of x. Plot the points, and connect
them with two smooth curves. Because division by 0
is undefined, the function is undefined when x = 0.
x
–2
–4
–6
–8
y
–20
–10
– 20
3
–5
Holt McDougal Algebra 2
x
2
4
6
8
y
20
10
20
3
5
5-1
Variation Functions
When you want to find specific values in an inverse
variation problem, you can solve for k and then
use substitution or you can use the equation
derived below.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 5: Sports Application
The time t needed to complete a certain race
varies inversely as the runner’s average speed s.
If a runner with an average speed of 8.82 mi/h
completes the race in 2.97 h, what is the average
speed of a runner who completes the race in 3.5 h?
t= k
s
Method 1 Find k.
Substitute.
2.97 = k
8.82
Solve for k.
k = 26.1954
t = 26.1954
s
3.5 = 26.1954
s
s ≈ 7.48
Holt McDougal Algebra 2
Use 26.1954 for k.
Substitute 3.5 for t.
Solve for s.
5-1
Variation Functions
Example 5 Continued
Method Use t1s1 = t2s2.
t1s1 = t2s2
(2.97)(8.82) = 3.5s
26.1954 = 3.5s
7.48 ≈ s
Substitute.
Simplify.
Solve for s.
So the average speed of a runner who completes
the race in 3.5 h is approximately 7.48 mi/h.
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 5
The time t that it takes for a group of volunteers to
construct a house varies inversely as the number
of volunteers v. If 20 volunteers can build a house
in 62.5 working hours, how many working hours
would it take 15 volunteers to build a house?
Method 1 Find k.
k
Substitute.
62.5 =
20
k
t=
Solve for k.
k = 1250
v
Use 1250 for k.
t = 1250
v
1250
Substitute 15 for v.
t=
15
1
t ≈ 83
Solve for t.
3
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 5 Continued
Method 2 Use t1v1 = t2v2.
t1v1 = t2v2
(62.5)(20) = 15t
1250 = 15t
1
83 ≈ t
3
Substitute.
Simplify.
Solve for t.
So the number of working hours it would take 15
volunteers to build a house is approximately 83 1
3
hours.
Holt McDougal Algebra 2
5-1
Variation Functions
You can use algebra to rewrite variation
functions in terms of k.
Notice that in direct variation, the ratio of the
two quantities is constant. In inverse variation,
the product of the two quantities is constant.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 6: Identifying Direct and Inverse Variation
Determine whether each data set represents a
direct variation, an inverse variation, or neither.
A.
B.
x
y
6.5
8
13 104
4 0.5
x
y
5
30
8
48
Holt McDougal Algebra 2
12
72
In each case xy = 52.
The product is constant,
so this represents an
inverse variation.
In each case y = 6. The
x
ratio is constant, so this
represents a direct
variation.
5-1
Variation Functions
Example 6: Identifying Direct and Inverse Variation
Determine whether each data set represents a
direct variation, an inverse variation, or neither.
C.
x
y
3
5
Holt McDougal Algebra 2
6
14
8
21
Since xy and y are not
x
constant, this is neither a
direct variation nor an
inverse variation.
5-1
Variation Functions
Check It Out! Example 6
Determine whether each data set represents a
direct variation, an inverse variation, or neither.
6a.
6b.
x
y
x
y
3.75 15
12
3
1
0.2
Holt McDougal Algebra 2
40
8
5
9
26
5.2
In each case xy = 45.
The ratio is constant, so
this represents an inverse
variation.
In each case y = 0.2.
x
The ratio is constant, so
this represents a direct
variation.
5-1
Variation Functions
A combined variation is a relationship that
contains both direct and inverse variation.
Quantities that vary directly appear in the
numerator, and quantities that vary inversely
appear in the denominator.
Holt McDougal Algebra 2
5-1
Variation Functions
Example 7: Chemistry Application
The change in temperature of an aluminum
wire varies inversely as its mass m and directly
as the amount of heat energy E transferred. The
temperature of an aluminum wire with a mass
of 0.1 kg rises 5°C when 450 joules (J) of heat
energy are transferred to it. How much heat
energy must be transferred to an aluminum
wire with a mass of 0.2 kg raise its temperature
20°C?
Holt McDougal Algebra 2
5-1
Variation Functions
Example 7 Continued
Step 1 Find k.
ΔT = kE
m
5 = k(450)
0.1
1
=k
900
Step 2 Use the variation
function.
Combined
Use 1 for k.
ΔT = E
variation
900m
900
Substitute.
E
20 =
Substitute.
900(0.2)
Solve for k.
3600 = E
Solve for E.
The amount of heat energy that must be
transferred is 3600 joules (J).
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 7
The volume V of a gas varies inversely as the
pressure P and directly as the temperature T.
A certain gas has a volume of 10 liters (L), a
temperature of 300 kelvins (K), and a
pressure of 1.5 atmospheres (atm). If the gas
is heated to 400K, and has a pressure of 1
atm, what is its volume?
Holt McDougal Algebra 2
5-1
Variation Functions
Check It Out! Example 7
Step 1 Find k.
Step 2 Use the variation
function.
kT
Combined
V=
Use 0.05 for
0.05T
P
V=
variation
k.
P
10 = k(300) Substitute.
1.5
V =0.05(400) Substitute.
(1)
Solve for k.
0.05 = k
Solve for V.
V = 20
The new volume will be 20 L.
Holt McDougal Algebra 2
5-1
Variation Functions
Lesson Quiz: Part I
1. The volume V of a pyramid varies jointly as the
area of the base B and the height h, and
V = 24 ft3 when B = 12 ft2 and h = 6 ft. Find B
when V = 54 ft3 and h = 9 ft.
18 ft2
2. The cost per person c of chartering a tour bus
varies inversely as the number of passengers
n. If it costs $22.50 per person to charter a
bus for 20 passengers, how much will it cost
per person to charter a bus for 36 passengers?
$12.50
Holt McDougal Algebra 2
5-1
Variation Functions
Lesson Quiz: Part II
3. The pressure P of a gas varies inversely as its
volume V and directly as the temperature T. A
certain gas has a pressure of 2.7 atm, a
volume of 3.6 L, and a temperature of 324 K.
If the volume of the gas is kept constant and
the temperature is increased to 396 K, what
will the new pressure be?
3.3 atm
Holt McDougal Algebra 2